Mutational analysis of the Drosophila sister-chromatid cohesion protein ORD and its role in the maintenance of centromeric cohesion

The ord gene is required for proper segregation of all chromosomes in both male and female Drosophila meiosis. Here we describe the isolation of a null ord allele and examine the consequences of ablating ord function. Cytologically, meiotic sister-chromatid cohesion is severely disrupted in flies lacking ORD protein. Moreover, the frequency of missegregation in genetic tests is consistent with random segregation of chromosomes through both meiotic divisions, suggesting that sister cohesion may be completely abolished. However, only a slight decrease in viability is observed for ord null flies, indicating that ORD function is not essential for cohesion during somatic mitosis. In addition, we do not observe perturbation of germ-line mitotic divisions in flies lacking ORD activity. Our analysis of weaker ord alleles suggests that ORD is required for proper centromeric cohesion after arm cohesion is released at the metaphase I/anaphase I transition. Finally, although meiotic cohesion is abolished in the ord null fly, chromosome loss is not appreciable. Therefore, ORD activity appears to promote centromeric cohesion during meiosis II but is not essential for kinetochore function during anaphase.     

Myocardial infarction and regulatory myosin light chain

Myosin from cardiac muscle consists of two heavy chains and two pairs of light chain. Regulatory myosin light chain (RMLC) is phosphorylated by a Ca2+ and calmodulin dependent myosin light chain kinase. The impact of experimental myocardial infarction on cardiac RMLC was studied. The left anterior descending coronary artery of rabbits was ligated. Three, 7 and 14 days later the animals were euthanized, sections of the heart were frozen in liquid nitrogen and later subjected to 2-dimensional electrophoresis. Isoelectric focusing was carried out at a pH range of 4.5-5.4. Reproducible patterns of protein separation showed four spots with proteins of phosphorylatable regulatory light chains shifted to a more negative pH as compared to essential light chain. We investigated changes in phosphorylation of RMLC in infarcted heart muscle. As compared to sham operated animals, a decline in phosphorylation of RMLC was present in both infarcted and non-infarcted portions of the left ventricle; the latter was significant 7 days following the onset of ischemia. In contrast, the decline in percent phosphorylation in the infarcted area was not significant. The amount of RMLC decreased significantly in the infarcted portion. A highly significant reduction in the percent of viable cardiomyocytes accompanied the decline in phosphorylation. There was a significant correlation of RMLC following administration of isoproterenol, 7 and 14 days following onset of ischemia. Only faint traces of essential atrial myosin light chain (ALC-1) were present in the non-infarcted portion of the left ventricle. No correlation was found between percent phosphorylation and the amount of RMLC (density) following infusion of saline or isoproterenol. Isoproterenol significantly increased percent phosphorylation without altering the amount of RMLC protein. We conclude that myocardial infarction profoundly affects regulatory myosin light chain phosphorylation in the infarcted and non-infarcted areas of the myocardium and that RMLC plays a significant part in myocardial contractility.     

Occupational medicine in Canada and Poland in the 1990s

The protocol describes (i) methods for the investigation of neuropeptide catabolism in the central nervous system (CNS), (ii) the identification of the neuropeptidases involved, and (iii) methods for the determination of neuropeptide stability in vitro. These methods are applicable also to study the degradation of peptide hormones by peripheral cells or tissues. To identify peptide degradation products, nanomolar amounts (micromolar concentrations) of peptides are incubated in synthetic media with cell or tissue cultures. Aliquots of the supernatants are withdrawn after different times, peptide fragments separated and fractionated by reversed-phase HPLC, and identified by peptide chemical methods. The peptidases responsible for this degradation can be identified by the use of specific inhibitors listed in the protocol. For receptor binding assays or the study of peptide effects in physiological, nanomolar concentrations the stability of the peptides in an in vitro system should be checked by addition of radiolabeled peptides (femtomolar or nanomolar concentrations) and monitoring the peptide degradation by a procedure analogous to that established for unlabeled peptides. The addition of more or less specific peptidase inhibitors enhances peptide stability in vitro, and thus it can be assured that a given peptide concentration is maintained during biological assays.     

The N-terminal domain of human GABA receptor rho1 subunits contains signals for homooligomeric and heterooligomeric interaction

gamma-Aminobutyric acid type C (GABAC) receptors identified in retina appear to be composed of GABA rho subunits. The purpose of this study was to localize signals for homooligomeric assembly of rho1 subunits and to investigate whether the same region contained signals for heterooligomeric interaction with rho2 subunits. In vitro translated human rho1 was shown to be membrane-associated, and proteinase K susceptibility studies indicated that the N terminus was oriented in the lumen of ER-derived microsomal vesicles. This orientation suggested the involvement of the N terminus of rho1 in the initial steps of subunit assembly. To test this hypothesis, mutants were created containing only N-terminal sequences (N-rho1) or C-terminal sequences (C-rho1) of rho1. Co-immunoprecipitation studies revealed that N-rho1, but not C-rho1, interacted with rho1 in vitro. When coexpressed in Xenopus oocytes, N-rho1 interfered with rho1 receptor formation. Together, these data suggested that signals for rho1 homooligomeric assembly reside in the N-terminal half of the subunit. Sequential immunoprecipitations were then performed upon cotranslated rho1 and rho2 subunits which demonstrated that rho1 and rho2 interacted in vitro. Co-immunoprecipitation indicated that N-rho1 specifically associated with rho2. Therefore, the N-terminal regions of rho subunits contain the initial signals for both homooligomeric and heterooligomeric assembly into receptors with GABAC properties.